1. The immunobiology of natural killer cells and bone marrow allograft rejection 
Isabel Barao, William J Murphy 
Biology of Blood and Marrow Transplantation 
Volume 9, Issue 12, Pages (December 2003)
DOI: /j.bbmt

2. Figure 1
BMC and solid-organ rejection was originally observed in mice. After lethal irradiation, mice remained capable of resisting allogeneic (A into B) BMC and solid organ grafts, as reflected by low engraftment rates. In addition, (A×B) F1 hybrid mice were capable of resisting parental BMC grafts in what was termed hybrid resistance but were able to accept solid-organ grafts. It is interesting to note that BMC grafts from F1 hybrid mice were only weakly resisted by parental mice, and solid-organ grafts were totally resisted by parental mice.
Biology of Blood and Marrow Transplantation 2003 9, DOI: ( /j.bbmt )

3. Figure 2
NK cells express multiple inhibitory and activating cell-surface receptors that belong to the immunoglobulin superfamily (KIR), C-like lectin family (CD94), NKG2 A, B, and C, and immunoglobulin-like molecule family (NKps and NKG2D). Some receptors bind either classic (HLA-A, -B, and -C) or nonclassic (HLA-E and -G) MHC class I ligands or have binding specificity for non-MHC class I molecules (immunoglobulin G, MICA/B, and ULBPs). a, Inhibitory receptors are distinguished by ITIM domains in their cytoplasmic tails, which on activation attract tyrosine phosphatase-1 phosphatases and send a potent inhibitory signal to the nucleus of NK cells, preventing them from killing certain targets. b, Activating receptors initiate cytokine production and NK-cell cytotoxicity. These receptors have short cytoplasmic domains but are associated with adapter proteins, such as DAP12, DAP10, and FcR. On binding to ligand, the adapter molecules send activating signals to the NK-cell nucleus via their intracytoplasmic ITAM tails. The ligands for NKps receptors are unknown but are not likely to be MHC molecules. NK cells also express the activating Fc receptor CD16 for immunoglobulin. Mouse NK cells express similar MHC-binding receptors, termed Ly49 molecules.
Biology of Blood and Marrow Transplantation 2003 9, DOI: ( /j.bbmt )

4. Figure 3
In vivo model to assess BMC engraftment. Mice were given cytoreductive conditioning in the form of lethal total body irradiation and were then intravenously infused with allogeneic BMCs. BMC engraftment was assessed through a splenic CFU-C assay or by measuring the splenic incorporation of 125IUdR, which is a DNA precursor analog. The spleen is the primary organ to repopulate with hematopoietic cells. For the CFU-C assay, a spleen suspension with a known amount of cells was plated in soft agar with exogenous cytokines (ie, IL-3 and GM-CSF), and 7 to 10 days later, the extent of colony formation was determined. The 125IUdR assay involves injection of this radioisotope in vivo, followed by the removal of the spleens 5 to 7 days after BMC transplantation and measurement of radioactivity in a gamma counter. The 125IUdR assay is less specific for hematopoietic cells, because all rapidly proliferating cells will be detected. Donor cell chimerism was also determined 40 days after transplantation.
Biology of Blood and Marrow Transplantation 2003 9, DOI: ( /j.bbmt )

5. Figure 4
Potential role of NK-cell subsets in BMC rejection. Allogeneic BMC (in this case, H-2d BMC in H-2b recipients) can be resisted by NK cells that do not have inhibitory Ly49 receptors (containing ITIM) for H-2Kd (ie, Ly49C/I+ subset) and have activating receptors (associated with ITAM) for H-2Kd (ie, Ly49D+ subset). NK-cell subsets expressing inhibitory receptors for H-2Kd (ie, Ly49A+ or Ly49G2+ subset) will become inactivated on interaction with the BMC, even in the presence of activating receptors. Possibly Ly49D NK cells are activated to reject H-2d BMC through other yet-unknown activating receptors.
Biology of Blood and Marrow Transplantation 2003 9, DOI: ( /j.bbmt )

6. Figure 5
NK cells can suppress GVHD and mediate allogeneic BMT and GVT effects through various pathways. Donor NK cells promote donor BMC engraftment, presumably through the production of hematopoietic growth factors (ie, GM-CSF, granulocyte cell-stimulating factor, IL-1, and IL-6). NK cells of donor type are also able to prevent GVH reactions. These effectors can suppress donor T cells through production of the immunosuppressive cytokine TGF-β or prevent T-cell priming by eliminating host dendritic cells. Increased donor engraftment can also be achieved through the suppression of host effector cells (NK and T cells), thus preventing graft rejection. Finally, donor NK cells can mediate GVT effects through direct cytotoxicity (perforin/granzymes, FasL, and tumor necrosis factor-related apoptosis-inducing ligand), secretion of cytokines (TNF-α and IFN-γ), or both.
Biology of Blood and Marrow Transplantation 2003 9, DOI: ( /j.bbmt )

7. Figure 6
Regulation of NK-cell responses by inhibitory receptors. a, KIR ligand match in HLA-mismatched BMT—donor NK cells have inhibitory receptors that recognize and bind MHC class I molecules on host tumor cells (ie, KIR2DL1:HLA-C w4), and inhibition of lysis occurs. b, KIR ligand mismatch in HLA-mismatched BMT—inhibitory receptors on donor NK cells do not recognize MHC class I molecules expressed on host tumor cells (ie, KIR2DL1:HLA-C w3), and lysis occurs. The activating receptor (AR) binds the corresponding activating ligand (AL), and NK cell-mediated cytotoxicity is triggered. KIR mismatch exerts a potent GVT effect and graft alloreactivity.
Biology of Blood and Marrow Transplantation 2003 9, DOI: ( /j.bbmt )